Structured state preparation in QCQMC improves energy accuracy over pure variational methods across molecular, condensed-matter, nuclear, and graph problems.
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Proton-neutron entanglement entropy is shown to track the formation of the island of inversion in Ne, Mg, and Si isotopes, with mutual information revealing stronger proton-neutron correlations in excited states than in ground states.
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A unified quantum computing quantum Monte Carlo framework through structured state preparation
Structured state preparation in QCQMC improves energy accuracy over pure variational methods across molecular, condensed-matter, nuclear, and graph problems.
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Entanglement study in the island of inversion region using \textit{ab initio} approach
Proton-neutron entanglement entropy is shown to track the formation of the island of inversion in Ne, Mg, and Si isotopes, with mutual information revealing stronger proton-neutron correlations in excited states than in ground states.